材料科学
尖晶石
密度泛函理论
电解质
锂钴氧化物
化学工程
煅烧
离子
涂层
电化学
锂(药物)
化学物理
锂离子电池
纳米技术
电池(电)
化学
物理化学
电极
计算化学
热力学
医学
功率(物理)
物理
生物化学
有机化学
内分泌学
工程类
冶金
催化作用
作者
Min Xu,Bifu Sheng,Yong Cheng,Junjie Lu,Minfeng Chen,Peng Wang,Bo Liu,Jizhang Chen,Xiang Han,Ming‐Sheng Wang,Siqi Shi
出处
期刊:Nano Research
[Springer Science+Business Media]
日期:2023-12-29
卷期号:17 (5): 4192-4202
被引量:28
标识
DOI:10.1007/s12274-023-6361-z
摘要
LiNi0.5Mn1.5O4 (LNMO) with a spinel crystal structure presents a compelling avenue towards the development of economic cobalt-free and high voltage (∼ 5 V) lithium-ion batteries. Nevertheless, the elevated operational voltage of LNMO gives rise to pronounced interfacial interactions between the distorted surface lattices characterized by Jahn–Teller (J–T) distortions and the electrolyte constituents. Herein, a localized crystallized coherent LaNiO3 and surface passivated Li3PO4 layer is deposited on LNMO via a one-step calcination process. As evidenced by transmission electron microscopy (TEM), time-of-flight secondary ion mass spectrometry (ToF-SIMS) and density functional theory (DFT) calculation, the epitaxial growth of LaNiO3 along the LNMO lattice can effectively stabilize the structure and inhibit irreversible phase transitions, and the Li3PO4 surface coating can prevent the chemical reaction between HF and transition metals without sacrificing the electrochemical activity. In addition, the ionic conductive Li3PO4 and atomic wetting inter-layer enables fast charge transfer transport property. Consequently, the LNMO material enabled by the lattice bonding and surface passivating features, demonstrates high performance at high current densities and good capacity retention during long-term test. The rational design of interface coherent engineering and surface coating layers of the LNMO cathode material offers a new perspective for the practical application of high-voltage lithium-ion batteries.
科研通智能强力驱动
Strongly Powered by AbleSci AI